EP3384681A1 - Liaison de longueur d'onde de pon pour services à haut débit - Google Patents

Liaison de longueur d'onde de pon pour services à haut débit

Info

Publication number
EP3384681A1
EP3384681A1 EP16810576.5A EP16810576A EP3384681A1 EP 3384681 A1 EP3384681 A1 EP 3384681A1 EP 16810576 A EP16810576 A EP 16810576A EP 3384681 A1 EP3384681 A1 EP 3384681A1
Authority
EP
European Patent Office
Prior art keywords
wavelength
data
frame
over
wavelengths
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
EP16810576.5A
Other languages
German (de)
English (en)
Other versions
EP3384681B1 (fr
Inventor
Thomas DETWILER
Richard Lee Goodson
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Adtran Holdings Inc
Original Assignee
Adtran Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Adtran Inc filed Critical Adtran Inc
Publication of EP3384681A1 publication Critical patent/EP3384681A1/fr
Application granted granted Critical
Publication of EP3384681B1 publication Critical patent/EP3384681B1/fr
Active legal-status Critical Current
Anticipated expiration legal-status Critical

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Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04QSELECTING
    • H04Q11/00Selecting arrangements for multiplex systems
    • H04Q11/0001Selecting arrangements for multiplex systems using optical switching
    • H04Q11/0062Network aspects
    • H04Q11/0067Provisions for optical access or distribution networks, e.g. Gigabit Ethernet Passive Optical Network (GE-PON), ATM-based Passive Optical Network (A-PON), PON-Ring
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B10/00Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
    • H04B10/27Arrangements for networking
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04JMULTIPLEX COMMUNICATION
    • H04J14/00Optical multiplex systems
    • H04J14/02Wavelength-division multiplex systems
    • H04J14/0227Operation, administration, maintenance or provisioning [OAMP] of WDM networks, e.g. media access, routing or wavelength allocation
    • H04J14/0254Optical medium access
    • H04J14/0256Optical medium access at the optical channel layer
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04JMULTIPLEX COMMUNICATION
    • H04J14/00Optical multiplex systems
    • H04J14/02Wavelength-division multiplex systems
    • H04J14/0278WDM optical network architectures
    • H04J14/0282WDM tree architectures
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04QSELECTING
    • H04Q11/00Selecting arrangements for multiplex systems
    • H04Q11/0001Selecting arrangements for multiplex systems using optical switching
    • H04Q11/0062Network aspects
    • H04Q2011/0064Arbitration, scheduling or medium access control aspects
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04QSELECTING
    • H04Q11/00Selecting arrangements for multiplex systems
    • H04Q11/0001Selecting arrangements for multiplex systems using optical switching
    • H04Q11/0062Network aspects
    • H04Q2011/0088Signalling aspects

Definitions

  • This specification relates to Passive Optical Network (PON) wavelength bonding.
  • PON Passive Optical Network
  • downstream/upstream wavelength and using two wavelengths would increase the peak rate to 17.34 Gbps per downstream/upstream.
  • One innovative aspect of the subject matter described in this specification can be embodied in methods for improving bandwidth available to individual packet flow between an Optical Line Terminal (OLT) and an Optical Network Unit (ONU) on a Passive Optical Network (PON) by bonding multiple wavelengths available to both the OLT and the ONU.
  • One example computer- implemented method includes transmitting, by a first telecommunications device, one or more data frames over multiple wavelengths simultaneously, the one or more data frames distributed across the multiple wavelengths over multiple fixed-length segments, receiving, by a second telecommunications device, the multiple fixed-length segments over the multiple wavelengths, and reassembling, by the second
  • the received multiple fixed-length segments based on
  • Another example computer-implemented method includes transmitting, over a first wavelength and by an OLT, a first frame of data to a first ONU, transmitting, over a second wavelength and by the OLT, a first portion of a second frame of data to a second ONU while the first frame of data is being transmitted to the first ONU over the first wavelength, and after transmission of the first frame of data over the first wavelength has completed and while the first portion of the second frame of data is still being transmitted to the second ONU over the second wavelength, transmitting a second portion of the second frame of data to the second ONU over the first wavelength.
  • Methods can further include receiving the second frame of data, determining, prior to transmitting the first portion of the second frame of data, when transmission of the first frame of data over the first wavelength will be completed, and determining, based on when transmission of the first frame of data over the first wavelength will be completed, the first portion of the second frame of data that will be transmitted over the second wavelength and the second portion of the second frame of data that will be transmitted over the first wavelength.
  • Methods can further include identifying a specified wavelength order that specifies an order in which portions of a single data frame are to be transmitted over available wavelengths. Transmitting the first portion of the second frame of data over the second wavelength comprises transmitting the first portion of the second frame of data over a given wavelength that is highest in the wavelength order and is available to transmit data while the first frame of data is being transmitted over the first wavelength. Transmitting the second portion of the second frame of data over the first wavelength comprises the following operations: determining that the first wavelength is next highest in the wavelength order after the second wavelength, and transmitting the second portion of the second frame of data over the first wavelength based on the determination that the first wavelength is the next highest in the wavelength order.
  • Identifying the specified wavelength order may comprise identifying an NG-PON2 channel numbering corresponding to wavelengths being used to transmit data.
  • Methods can further include identifying a specified wavelength order that specifies an order in which portions of a single data frame are to be transmitted over available wavelengths, determining, based on the wavelength order, that the second wavelength is last in the wavelength order and that the first wavelength is first in the wavelength order, and in response to determining that the second wavelength is last in the wavelength order and that the first wavelength is first in the wavelength order, transmitting the second portion of the second frame of data over the first wavelength. Transmitting the second portion of the second frame of data over the first wavelength is based on the determination that the first wavelength is the first in the wavelength order.
  • Methods can further include transmitting a third frame of data to the second ONU over the first and second wavelengths based on a specified wavelength order.
  • the first and second wavelengths carry no traffic right before transmitting the third frame of data.
  • Various portions of the third frame of data are assigned round robin to the first and second wavelengths.
  • an 8 bytes header is added with payload length for the third frame of data.
  • the first portion of the second frame of data and the second portion of the second frame of data are both transmitted to the second ONU without a sequence number.
  • Various portions of the second frame of data are assigned to various different wavelengths based on a specified ordering of the wavelengths.
  • Frames of data are divided into 4 bytes segments or any other size of segments (e.g., 8 bytes segments, 16 bytes segments).
  • the OLT may implement a dynamic allocation algorithm using wavelength as a parameter in bandwidth allocation for bonded entities.
  • the dynamic allocation algorithm allocates time grants for different wavelengths of a bonded Transmission Container (TCONT) based on which wavelengths will be available and how much data is being transmitted when in a bonded mode of operation.
  • TCONT bonded Transmission Container
  • the methods, devices, and/or systems described in the present disclosure can synchronize and time equalize bit streams of a packet flow, for example, between an OLT and an ONU, on multiple wavelengths. Different portions (e.g., fixed size segments) of a given packet in the packet flow are distributed on the multiple wavelengths at one end of a communications path (e.g., at the OLT) on-demand at real-time basis, and combined at the other end of the communications path (e.g., the ONU).
  • a communications path e.g., at the OLT
  • the ONU the other end of the communications path
  • the disclosed method enables an OLT to dynamically balance loads according to offered non-bonded load (e.g., traffic carried by a single wavelength) and bonded load (e.g., traffic carried by multiple wavelengths in a bonding group), since bonded loads are distributed on available wavelengths in a bonding group on-demand, at real-time basis.
  • non-bonded load e.g., traffic carried by a single wavelength
  • bonded load e.g., traffic carried by multiple wavelengths in a bonding group
  • FIG. 1 A is a block diagram illustrating an example networking environment for Passive Optical Network (PON) wavelength bonding.
  • PON Passive Optical Network
  • FIG. IB is a block diagram illustrating an example ONU management and control interface (OMCI) for PON wavelength bonding.
  • OMCI ONU management and control interface
  • FIG. 2 is a diagram illustrating an example wavelength bonding scheme for transmitting a bonded frame.
  • FIG. 3 A is a diagram illustrating example received frames prior to delay equalization.
  • FIG. 3B is a diagram illustrating example received frames after delay equalization.
  • FIG. 4 is a diagram illustrating an example Framing Sublayer (FS) pay load carrying bonded frames and non-bonded frames.
  • FS Framing Sublayer
  • FIG. 5 is a diagram illustrating an example wavelength bonding scheme for demultiplexing Service Data Units (SDUs) across multiple wavelengths.
  • SDUs Service Data Units
  • FIG. 6 is a flow chart of an example process for PON wavelength bonding.
  • FIG. 7 is a flow chart of an example scheduling process for PON wavelength bonding of the downstream transmission.
  • This document describes methods, systems, and apparatus for improving bandwidth available to individual packet flow on a Passive Optical Network (PON) by bonding multiple links (e.g., wavelengths).
  • PON Passive Optical Network
  • telecommunications device e.g., an Optical Line Terminal (OLT)
  • OLT Optical Line Terminal
  • telecommunications device can predetermine how many bytes of the bonded packet are to be sent on each bonded wavelength, so that transmissions of various portions of the bonded packet on the bonded wavelengths end at the same time or substantially simultaneously.
  • this disclosure refers to passive optical telecommunications systems for purposes of example, the subject matter of this document can be applied to other types of telecommunications systems or other systems that offer multiple wavelengths for data transmission.
  • a Passive Optical Network such as a Next-Generation Passive Optical Network 2 (NG-PON2) or a 10 Gbps Ethernet Passive Optical Network (10G- EPON), can provide 10 Gbps data rate per wavelength (not accounting for various overhead).
  • PON a Passive Optical Network
  • NG-PON2 Next-Generation Passive Optical Network 2
  • 10G- EPON 10 Gbps Ethernet Passive Optical Network
  • an OLT with multiple optical transceivers e.g., multiple ports operating at different wavelengths
  • the ONU may have multiple optical transceivers (i.e., a bonding-capable ONU with multiple tunable lasers) so that the ONU can receive data from the OLT on multiple wavelengths downstream and transmit data to the OLT on multiple wavelengths upstream.
  • multiple optical transceivers i.e., a bonding-capable ONU with multiple tunable lasers
  • an OLT can ascertain aggregate capabilities in both downstream and upstream directions (e.g., how many wavelengths each ONU can use in both downstream and upstream directions) of its attached ONUs through standard discovery mechanisms (e.g. physical layer operations, administration and maintenance (PLOAM) or ONU management and control interface (OMCI) in NG-PON2, or multi-point control protocol (MPCP) or Ethernet OAM in 10G-EPON).
  • PLOAM physical layer operations, administration and maintenance
  • OMCI ONU management and control interface
  • MPCP multi-point control protocol
  • Ethernet OAM in 10G-EPON
  • the OLT can bond multiple wavelengths to transmit data to the ONU downstream and the ONU can bond multiple wavelengths to transmit data to the OLT upstream.
  • Not all ONUs in a PON are required to participate in wavelength bonding.
  • not all active wavelengths in a PON are required to carry bonded traffic.
  • the service and/or traffic flows can be aware of the wavelength bonding (e.g., which ONU is a bonding-capable ONU, which wavelength can carry bonded traffic).
  • Wavelengths bonding can be achieved independently in the upstream and downstream directions, and can span a variable number of wavelengths. Any telecommunications systems with multiple wavelengths may benefit from the subject matter described in this document.
  • FIG. 1 A is a block diagram illustrating an example networking environment 100 in which wavelengths in a passive optical network (PON) can be bonded for providing high-rate low-latency services to individual packet flow.
  • the environment 100 includes a PON 102 that connects users to a network 104.
  • the environment 100 may include additional and/or different components not shown in the block diagram, such as one or more active optical networks (AONs), another type of network that provides network services (e.g., ADSL2+, VDSL2, etc.), or a combination of these and other technologies.
  • AONs active optical networks
  • ADSL2+ e.g., ADSL2+, VDSL2, etc.
  • components may also be omitted from the environment 100.
  • the PON 102 includes an OLT 106 at a service provider's central office (or other distribution point), an ONU 110 near residential locations 116, an ONU 112 near business locations 118, an ONU 114 near wireless communications equipment 120, a fiber optic link 122 connecting the OLT 106 and the ONU 110, a fiber optic link 124 connecting the OLT 106 and the ONU 112, and a fiber optic link 126 connecting the OLT 106 and the ONU 114.
  • the OLT 106 is coupled to a number of ONUs 110, 112, and 114 (also referred to as optical network terminals (ONTs)), which are located near end users, thereby forming a point-to-multipoint network.
  • ONTs optical network terminals
  • NG-PON2 Next-Generation Passive Optical Network 2
  • a single OLT port can connect to 64 (or another number of) different ONUs.
  • the NG-PON2 uses logical multiplexing in a downstream direction and time-division multiplexing in an upstream direction.
  • Each ONU can include, or otherwise be coupled to, one or more customer-premises equipment (CPE) or subscriber devices (e.g., CPE modems).
  • CPE customer-premises equipment
  • subscriber devices e.g., CPE modems
  • the ONU 110 is a device that terminates the PON 102 at the customer end, and provides a service connection to a user living in the residential locations 116.
  • the ONU 110 terminates optical fiber transmission, and can transform incoming optical signals into electrical signals, adapted for processing by subscriber devices.
  • ONUs can provide network services, for example, to residential locations 116, business locations 118, or other forms of communications infrastructure, such as wireless communications equipment 120.
  • Each ONU can include one or more optical transceivers (e.g., one or more tunable lasers).
  • the ONU 110 includes one optical transceiver that can receive data from the OLT (or transmit data to the OLT) on a single wavelength ⁇ .
  • the ONU 112 includes multiple optical transceivers that can receive data from the OLT (or transmit data to the OLT) on three wavelengths ⁇ , b, and U.
  • the ONU 114 includes one optical transceiver that can receive data from the OLT (or transmit data to the OLT) on a single wavelength b.
  • the ONU 110 can receive non-bonded data from the OLT (or transmit non-bonded data to the OLT) on a single wavelength ⁇ .
  • the ONU 112 e.g., a bonding-capable ONU
  • the ONU 114 can receive non- bonded data from the OLT (or transmit non-bonded data to the OLT) on a single wavelength b.
  • the disclosed subject matter does not require all ONUs on a same PON to support multiple wavelengths or bonding.
  • the OLT 106 as a network distribution element, provides an interface between the PON 102 and the network 104, and serves as the service provider's endpoint of the PON 102.
  • the OLT 106 transmits downstream data traffic to ONUs (e.g., ONUs 110, 112, and 114), and receives upstream data traffic from the ONUs.
  • ONUs e.g., ONUs 110, 112, and 114
  • the OLT 106 includes a bonding engine 108 that can detect and identify a bonding-capable ONU on the PON 102.
  • the bonding engine 108 can detect and identify the ONU 112 as a bonding-capable ONU when the ONU 112 registers with the OLT 106.
  • the bonding engine 108 can ascertain aggregate capabilities in both downstream and upstream directions between the OLT 106 and its attached ONUs through standard discovery mechanisms.
  • the OLT 106 will communicate with them according to, for example, an ITU PON standard (e.g., the NG-PON2 standard) or an IEEE PON standard (e.g., the 10G-EPON standard).
  • the bonding engine 108 can allocate multiple wavelengths (e.g., ⁇ , b, andb) in a bonding group between the ONU and the OLT 106 jointly/simultaneously, for the purpose of bonding data paths between the ONU and the OLT 106 together.
  • multiple wavelengths e.g., ⁇ , b, andb
  • Bonding can be achieved independently in the upstream and downstream directions, and can span a variable number of wavelengths between the ONU and the OLT 106.
  • the bonding engine 108 can determine, in advance, when each wavelength among multiple wavelengths in a bonding group between the OLT 106 to the ONU 112 will be available for transmitting a bonded packet (e.g., by checking transmission schedule on each wavelength).
  • the bonding engine 108 can assign various portions of the packet to the multiple wavelengths in the bonding group in a round robin way according to a specified wavelength order known to both the OLT 106 and the ONU 112 (e.g., stored in a memory of the OLT 106 and similarly stored in a memory of the ONU 112). For example, the OLT 106 can inform the ONU 112 of the wavelength order through a management channel, or the order could be established a priori such as according to ascending or descending wavelength.
  • the ONU 112 can use a delay equalization technique to align data reception across the synchronous data paths (e.g., ordered wavelengths) and reassemble the packet according to the specified wavelength order.
  • a delay equalization technique to align data reception across the synchronous data paths (e.g., ordered wavelengths) and reassemble the packet according to the specified wavelength order.
  • the bonding engine 108 can determine in advance when each wavelength in the bonding group will be available for transmitting the bonded packet (e.g., by checking a transmission schedule on each wavelength). The bonding engine 108 can predetermine how many bytes of the bonded packet are to be sent on each wavelength, so that transmissions of various portions of the bonded packet on the multiple wavelengths end at the same time or substantially simultaneously. The bonding engine 108 can start sending portions of the bonded packet on one or more idle wavelengths.
  • the bonding engine 108 can start sending other portions of the bonded packet on these one or more now-available wavelengths to minimize latency of transmitting the packet.
  • Various portions of the packet are allocated on the multiple wavelengths in a round robin way according to a specified wavelength order as discussed above.
  • the bonding engine 108 can balance the traffic load by not allocating bonded traffic on the particular wavelength.
  • the bonding engine 108 can implement Dynamic Bandwidth Allocation (DBA) routines on each wavelength.
  • the DBA routines on each wavelength can process grants to bonding-capable ONUs such that the same Allocation Identifier (Alloc-ID) (or Logical Link layer ID (LLID) for 10G-EPON) is identified in the upstream direction to begin transmission on multiple wavelengths.
  • the bonding engine 108 can send bandwidth maps (BWmaps) for each wavelength to the ONU 112, and the ONU 112 can identify the same Alloc-ID in received BWmaps for multiple wavelengths.
  • BWmaps bandwidth maps
  • the ONU 112 can allocate bonded data on the multiple wavelengths similar to the downstream direction, using a single bonded Transmission Container (bT-CONT) per wavelength corresponding to the Alloc-ID.
  • the DBA routines on each wavelength can make the grants occur on different wavelengths at the same time, which in some cases leads to lower latency for traffic flows.
  • the DBA routines on each wavelength can assign varying amounts of time per wavelength in order to optimize the DBA scheduling across offered load, which includes balancing bonded load and non-bonded load leading to higher throughput utilization in some cases.
  • DBA could use multiple grants on multiple wavelengths per XGTC frame to minimize latency.
  • the new elements related to bonding in the ONU and OLT need to be managed.
  • the ONU is managed via OMCI (ONU management and control interface).
  • the ONU is managed via Ethernet OAM.
  • PONs may also be managed via SNMP, NETCONF/YANG or other management protocols.
  • OMCI ONU management and control interface
  • NETCONF/YANG NETCONF/YANG or other management protocols.
  • FIG. IB a relational diagram such as shown in FIG. IB gives a representation of functions in the ONU so that they can be managed.
  • a management representation of the bonded XGEM port and bonded T-CONT is needed.
  • a means e.g. bonded group list
  • bit streams on the bonded wavelengths can be delay-equalized (e.g., via digital signal buffering), so that a given packet can be distributed on, for example, multiple wavelengths ⁇ , b, and U between the OLT 106 and the ONU 112, and end at similar times on the multiple wavelengths ⁇ , b, and U. Due to the point-to-multipoint nature of a PON, delay equalization of multiple wavelengths can be performed at the receiver of the ONU 112 in the downstream direction. In the upstream direction, equalization can be performed at both of or either of the transmitter of the ONU 112 and/or the receiver of the OLT 106.
  • both downstream and upstream transmissions can be synchronized with the reference clock of the OLT 106 in conformance with standard protocols (e.g. NG-PON2 and lOG-EPON). Synchronizing with the reference clock of the OLT 106 can allow the ONU 112 to insert delay in a digital parallel and/or serial data path to achieve delay equalization. For example, in a NG-PON2, delay equalization can result in 64-bit alignment between bonded wavelengths (e.g., the quanta defined for 10-Gigabit-capable Passive Optical Network (XG-PON)
  • Encapsulation Method (XGEM) payload and framing sublayer boundaries).
  • XGEM Encapsulation Method
  • the alignment can be made in 66-bit blocks defined by the reconciliation sublayer.
  • Other PON variations with higher speeds can achieve delay equalization at wider or narrower data width.
  • the operations performed by the bonding engine 108 can be implemented as operations performed by a data processing apparatus, on data stored on one or more computer-readable storage devices or received from other sources.
  • data processing apparatus encompasses all kinds of apparatus, devices, and machines for processing data, including, by way of example, a programmable processor, a computer, a system on a chip, or multiple ones, or combinations of the foregoing.
  • the bonding engine 108 can also be implemented as special purpose logic circuitry, for example, a field programmable gate array (FPGA) or an application specific integrated circuit (ASIC).
  • FPGA field programmable gate array
  • ASIC application specific integrated circuit
  • the network 104 facilitates wireless or wireline communications between the components of the PON 102 with any other local or remote computer, such as additional PONs, servers, or other devices communicably coupled to the network 104, including those not illustrated in FIG. 1A. As illustrated in FIG. 1 A, the network 104 is depicted as a single network, but may be comprised of more than one network without departing from the scope of this disclosure.
  • the network 104 may be all or a portion of an enterprise or secured network, or at least a portion of the network 104 may represent a connection to the Internet, a public switched telephone network (PSTN), a data server, a video server, or additional or different networks.
  • PSTN public switched telephone network
  • a portion of the network 104 may be a virtual private network (VPN).
  • VPN virtual private network
  • all or a portion of the network 104 can comprise either a wireline or wireless link.
  • Example wireless links may include 802.11 ac/ad/af/a/b/g/n, 802.20, WiMax, LTE, free-space optical links, and/or any other appropriate wireless link.
  • the network 104 encompasses any internal or external network, networks, sub-network, or combination thereof, operable to facilitate communications between various computing components, inside and outside the environment 100.
  • the network 104 may communicate, for example, Internet Protocol (IP) packets, Frame Relay frames, Asynchronous Transfer Mode (ATM) cells, voice, video, data, and other suitable information between network addresses.
  • IP Internet Protocol
  • ATM Asynchronous Transfer Mode
  • the network 104 may also include one or more local area networks (LANs), radio access networks (RANs), metropolitan area networks (MANs), wide area networks (WANs), all or a portion of the Internet, and/or any other communication system or systems at one or more locations.
  • LANs local area networks
  • RANs radio access networks
  • MANs metropolitan area networks
  • WANs wide area networks
  • FIG. 2 is a diagram illustrating an example wavelength bonding scheme 200 for transmitting a bonded frame when one or more wavelengths in a bonding group are transmitting non-bonded frames.
  • the scheme 200 shown in FIG. 2 illustrates how OLT 106 allocates multiple wavelengths to transmit a bonded frame to ONU 112 when non-bonded frames are being transmitted on two of the multiple wavelengths similar to those described in FIG. 1A.
  • the scheme 200 may include additional and/or different wavelengths not shown in the diagram. Wavelengths may also be omitted from the scheme 200.
  • XGTC Transmission Convergence
  • wavelengths ⁇ , b, and b at the OLT 106 For purposes of example, assume that all three wavelengths are idle at the beginning. Then, a non-bonded frame 202 is received by the OLT 106 to be transmitted to the ONU 114. The OLT 106 allocates the non- bonded frame 202 on wavelength b and transmits the non-bonded frame 202 to ONU 114 on the wavelength b, since the ONU 114 can only receive data from the OLT 106 on the wavelength b as described in FIG. 1 A. While the non-bonded frame 202 is being transmitted on wavelength b, another non-bonded frame 204 is received by the OLT 106 to be transmitted to the ONU 110.
  • the OLT 106 allocates the non-bonded frame 204 on wavelength ⁇ and transmits the non-bonded frame 204 to ONU 110 on the wavelength ⁇ , since the ONU 110 can only receive data from the OLT 106 on the wavelength ⁇ as described in FIG. 1 A.
  • Pre-emption is not supported in either the ITU-T PONs (e.g., NG- PON2) or the IEEE PONs (e.g., lOG-EPON).
  • a bonded frame 206 i.e., 206a-c
  • a bonded frame 206 is received by the OLT 106 to be transmitted to the ONU 112 on wavelengths ⁇ , b, and Xs in a bonding group
  • only wavelength X3 is idle while wavelengths Xi and X2 are busy transmitting the non-bonded frames 204 and 202, respectively.
  • the bonding engine 108 of the OLT 106 can allocate the bonded frame 206 on all three wavelengths in advance (e.g., before transmissions of non- bonded frames on wavelengths Xi and X2 have completed) and start transmitting allocated portions of the bonded frame 206a on currently available wavelength X3.
  • the bonded frame 206 is being transmitted at a data rate of a single wavelength (e.g., 8.67 Gbps).
  • wavelength X2 completes transmitting the non-bonded frame 202
  • allocated portions of the bonded frame 206b can be transmitted on the wavelength X2.
  • the bonded frame 206 is being transmitted at a data rate of two
  • wavelengths e.g., 17.34 Gbps.
  • allocated portions of the bonded frame 206c can be transmitted on the wavelength Xi.
  • the bonded frame 206 is being transmitted at a data rate of three wavelengths (e.g., 26 Gbps).
  • the bonding engine 108 pre-allocates the bonded frame 206 on all three wavelengths in a way that transmissions of various portions of the bonded frame 206 end at the same time or substantially simultaneously (e.g., within 6.4 nanoseconds when a bonded frame comprises multiple 64-bit words and 10 Gbps data rate is provided on each wavelength). For example, the bonding engine 108 needs to determine in advance when each wavelength in the bonding group will be available for transmitting the bonded frame (e.g., when current transmission of a non-bonded frame over a given wavelength will be completed).
  • the bonding engine 108 can predetermine how many bytes of the bonded frame are to be sent on each bonded wavelength, so that transmissions of various portions of the bonded frame on the bonded wavelengths end at the same time as shown in FIG. 2. In some cases, transmissions of various portions of the bonded frame on the bonded wavelengths may not end at the same time, rather end substantially simultaneously (as shown and discussed in FIG. 4 below). In doing so, the bonding mechanism used by the bonding engine 108 for downstream direction does not require fragmentation headers (other than one instance of the normal XGEM frame header for each wavelength that carries a packet), sequence numbers, or reassembly buffers to implement wavelength bonding in a PON. Instead, the delay equalization technique (discussed in FIG. 3B below) is used to align data reception across the synchronous data paths.
  • FIGS. 3A-3B are diagrams illustrating example received frames 300 prior to delay equalization and example received frames 350 after delay equalization.
  • the frames 300 and 350 shown in FIGS. 3A-3B are NG- PON2 frames.
  • the frames 300 and 350 may include additional and/or different wavelengths not shown in the diagram. Wavelengths may also be omitted from the frames 300 and 350.
  • FIG. 3A illustrates parallel data received, for example, at an ONU on two wavelengths (e.g., ⁇ and i) as a 64-bit aligned parallel data stream. Since data are received on two wavelengths, there is differential delay (or relative delay) between the two wavelengths. For example, on wavelength 1 (e.g., ⁇ ) the first Physical Synchronization Block downstream (PSBd) is received earlier than the first PSBd on wavelength 2 (e.g., i) due to the differential delay.
  • PSBd Physical Synchronization Block downstream
  • FIG. 3B illustrates the received frames at the ONU on two wavelengths (e.g., ⁇ and i) after delay equalization.
  • the NG-PON2 ONU can detect the differential delay between the two wavelengths from an OLT through measurement of the PSBd frame overhead and use that information to delay-equalize received frames (e.g., via digital signal buffering) on the two wavelengths. Alignment of PSBd overhead between wavelengths may be accomplished with concurrent PSBd headers, or with a known non-zero offset between PSBd overhead on different wavelength (as specified or dictated by means of control).
  • an ONU using EPON may use alignment markers such as those specified for 40GBASE-R or 100GBASE-R, or multipoint MAC control (MPCP) timestamps to assist in delay equalization. Other methods of detecting delay alignment are also possible. After delay equalization, alignment of underlying data is assured across wavelengths to 8-byte boundaries (other alignment quanta such as 4 bytes or 16 bytes are also possible). Since the Framing Sublayer (FS) header (FS Hdr) may contain variable length BWmap and PLOAMd, FS Hdr on the two wavelengths may finish at different times. As a result, FS Payload on the two wavelengths may start at different times.
  • FS Framing Sublayer
  • FIG. 4 is a diagram illustrating an example Framing Sublayer (FS) payload 400 carrying bonded frames and non-bonded frames (e.g., allocated by the bonding engine 108).
  • the frames in FIG. 4 are NG-PON2 frames.
  • the payload 400 may be carried by additional and/or different wavelengths not shown in the diagram. Wavelengths may also be omitted from the payload 400.
  • FS payload sections on both wavelengths are filled with both bonded XGEM (bXGEM) frames and non-bonded XGEM
  • uXGEM forward Error Correction
  • bXGEM 1 three bonded XGEM frames 402, 404, and 406 (e.g., denoted by bXGEM 1) are transmitted (not to scale) on wavelengths in a bonding group (e.g., wavelength 1 and 2).
  • the first section of the bonded XGEM frame 402 is carried exclusively by wavelength 1 since wavelength 2 carries a non-bonded frame (e.g., an uXGEM 2 frame).
  • a 64-bit word at a time of the first section of the bonded XGEM frame 402 is passed to a packet FIFO mechanism (e.g., at a data rate of roughly 8.67 Gbps accounting for Forward Error Correction (FEC)).
  • FEC Forward Error Correction
  • wavelength 2 After wavelength 2 completes transmission of the non-bonded frame, wavelength 2 joins wavelength 1 to carry second section of the bonded XGEM frame 402.
  • a 128-bit word at a time of the second section of the bonded XGEM frame 402 is passed to the packet FIFO mechanism (e.g., at a data rate of roughly 17.34 Gbps accounting for FEC).
  • wavelength 1 carries the first 64-bit of a given 128-bit word to be transmitted and wavelength 2 carries the subsequent 64- bit of the given 128-bit word, followed in the next timeslot by wavelength l 's 64-bit data and then wavelength 2's 64-bit data, and so on (e.g., transmitting alternately between wavelengths 1 and 2).
  • the bonded XGEM frame 402 finishes with 128-bit alignment on wavelengths 1 and 2.
  • Word sizes other than 64-bits may also be considered, for example 32-bit words or 128-bit words, though 64-bit words are illustrated for NG-PON2 since it is the base transmission quanta for XGEM payload.
  • first section of the bonded XGEM frame 404 is carried exclusively by wavelength 2 since wavelength 1 carries a non- bonded frame (e.g., an uXGEM 3 frame).
  • a 64-bit word at a time of the first section of the bonded XGEM frame 404 is passed to the packet FIFO mechanism (e.g., at a data rate of roughly 8.67 Gbps accounting for FEC).
  • wavelength 1 joins wavelength 2 to carry second section of the bonded XGEM frame 404.
  • a 128-bit word at a time of the second section of the bonded XGEM frame 404 is passed to the packet FIFO mechanism (e.g., at a data rate of roughly 17.34 Gbps accounting for FEC).
  • the bonded XGEM frame 404 finishes without 128-bit alignment on wavelengths 1 and 2, since the third section of the bonded XGEM frame 404 only has 64 bits and can be carried exclusively by wavelength 1.
  • wavelength 1 is transmitting the third section of the bonded XGEM frame 404, wavelength 2 is idle and can be used to carry a different frame, bonded or unbonded.
  • the entire frame begins on both wavelengths 1 and 2, and is carried 128-bits at a time for the duration of the frame (e.g., at a data rate of roughly 17.34 Gbps accounting for FEC).
  • wavelength 1 carries the first 64-bit of a given 128-bit word to be transmitted and wavelength 2 carries the subsequent 64-bit of the given 128-bit word, followed in the next timeslot by wavelength l 's 64-bit data and then wavelength 2's 64-bit data, and so on (e.g., transmitting alternately between wavelengths 1 and 2).
  • the bonded XGEM frame 406 finishes with 128-bit alignment on wavelengths 1 and 2.
  • FIG. 5 is a diagram illustrating an example wavelength bonding scheme 500 for demultiplexing Service Data Units (SDUs, e.g. XGEM-encapsulated Ethernet frames) across multiple wavelengths.
  • SDUs Service Data Units
  • the scheme 500 shown in FIG. 5 illustrates how, for example, the bonding engine 108 of the OLT 106 allocates multiple wavelengths to transmit a bonded frame to ONU 112 when non-bonded frames are being transmitted on two of the multiple wavelengths similar to those described in FIGS. 1 A and 2.
  • the scheme 500 may include additional and/or different wavelengths not shown in the diagram. Wavelengths may also be omitted from the scheme 500.
  • the frames in FIG. 5 are NG-PON2 frames and the bonded XGEM frame 502 comprising 150 bytes of data is divided into nineteen 64-bit (i.e., 8-byte) data segments (e.g., segment number 0 to segment number 18).
  • the bonded XGEM frame 502 can be divided into 4-bytes data segments or any other length data segments.
  • XGTC frame boundaries are aligned on three wavelengths ⁇ , b, and Xs at the OLT 106. At the beginning, all three wavelengths are idle. Then, a non-bonded XGEM frame 504 is received by the OLT 106 to be transmitted to the ONU 110.
  • the OLT 106 allocates the non-bonded XGEM frame 504 on wavelength Xi and transmits the non-bonded XGEM frame 504 to ONU 110 on the wavelength Xi, since the ONU 110 can only receive data from the OLT 106 on the wavelength Xi as described in FIG. 1 A. While the non- bonded XGEM frame 504 is being transmitted on wavelength Xi, another non-bonded XGEM frame 506 is received by the OLT 106 to be transmitted to the ONU 114.
  • the OLT 106 allocates the non-bonded XGEM frame 506 on wavelength b and transmits the non-bonded XGEM frame 506 to ONU 114 on the wavelength X2, since the ONU 114 can only receive data from the OLT 106 on the wavelength b as described in FIG. 1A.
  • the bonding engine 108 of the OLT 106 can allocate the bonded XGEM frame 502 on all three wavelengths according to a specified wavelength order known to both the OLT 106 and the ONU 112 in advance (e.g., before transmissions of non- bonded XGEM frames on wavelengths Xi and b have completed) and start transmitting allocated portions of the bonded XGEM frame 502 on currently available wavelength b.
  • the bonding engine 108 of the OLT 106 can determine when current transmission of non- bonded XGEM frames 504 and 506 over wavelengths Xi and b will be completed (e.g., by checking transmission schedule on each wavelength). Based on the determination, the bonding engine 108 can calculate how many 8-byte segments of the bonded XGEM frame 502 to be sent on each bonded wavelength, so that transmissions of various portions of the bonded XGEM frame 502 on the bonded wavelengths end at the same time or substantially simultaneously.
  • the bonding engine 108 allocates segment number 0-7, 10, 13, and 16 on wavelengths b, segment number 6, 9, 12, 15, and 18 on wavelengths b, and segment number 8, 11, 14, and 17 on wavelengths Xi.
  • segment number 0-7 In the example of a 150-byte XGEM frame, all segments numbered 0- 17 contain a full 8 bytes, and the final segment number 18 would contain only 6 bytes.
  • the amount of additional overhead data required to send this frame over the bXGEM instead of a single wavelength is the two bXGEM headers (8 bytes each) for activating different wavelengths.
  • the transmitter may choose to send bXGEM frames over all wavelengths (to minimize latency), and in other cases the transmitter may limit the number of wavelengths over which to send a bXGEM frame (to minimize overhead, hence maximizing throughput). In some cases, the transmitter may choose to send bXGEM frames over all wavelengths (to minimize latency), and in other cases the transmitter may limit the number of wavelengths over which to send a bXGEM frame (to minimize overhead, hence maximizing throughput). In some cases, the transmitter may choose to send bXGEM frames over all wavelengths (to minimize latency), and in other cases the transmitter may limit the number of wavelengths over which to send a bXGEM frame (to minimize overhead, hence maximizing throughput). In some cases, the transmitter may choose to send bXGEM frames over all wavelengths (to minimize latency), and in other cases the transmitter may limit the number of wavelengths over which to send a bXGEM frame (to minimize overhead, hence maximizing throughput). In some
  • the allocation is sent to a transmission scheduler.
  • a bXGEM header is inserted each time a bonded XGEM frame is started on wavelengths that are known to be in-service and operational at the OLT 106 and ONU 112 for the intended SDU.
  • the bXGEM header includes an XGEM id and payload length following the bXGEM header. For example, when the bonded XGEM frame 502 starts on X3, a bXGEM header, indicating bonded XGEM frame 502 and a data length of, for example, 80 bytes for ten 8-byte segments, is inserted before segment number 0.
  • a bXGEM header indicating bonded XGEM frame 502 and a payload length of, for example, 38 bytes for five 8-byte segments, is inserted before segment number 6.
  • a bXGEM header indicating bonded XGEM frame 502 and a payload length of, for example, 30 bytes for four 8-byte segments, is inserted before segment number 8.
  • a non-bonding ONU when a non-bonding ONU receives the bXGEM header, it knows that the bonded XGEM frame is not for it and will, for example, discard the data received for a period of time calculated based on the data length in the bXGEM header.
  • the bonded receiver e.g., the ONU 112
  • the bonded receiver when receiving a bXGEM header and payload on, for example, a second and subsequent wavelength (i.e., Xi), the bonded receiver knows the sequence of transmission across wavelengths X2 and X3 (e.g., the specified wavelength order known to the bonded receiver) and can reassemble the bonded XGEM frame 502.
  • FIG. 6 is a flow chart of an example process 600 for PON wavelength bonding.
  • the example process 600 can be performed, for example, by one or more telecommunications devices, such as those described with reference to FIG. 1A (e.g., OLT 106).
  • the example process 600 can also be implemented as instructions stored on a non-transitory, computer-readable medium that, when executed by one or more telecommunications devices, configures the one or more telecommunications devices to perform and/or causes the one or more telecommunications devices to perform the actions of the example process 600.
  • a first frame of data to a first optical network unit (ONU) is transmitted by an optical line terminal (OLT) over a first wavelength (605).
  • OLT optical line terminal
  • the first frame of data is a non-bonded frame of data and the first ONU is a non-bonding ONU.
  • a second frame of data is received by the OLT to be transmitted to a second ONU different than the first ONU (610).
  • the second frame of data is a bonded frame of data and the second ONU is a bonding-capable ONU.
  • the second frame of data is stored in a buffer for bonded data while the first frame of data is stored in a different buffer for non-bonded data.
  • a first portion of the second frame of data that will be transmitted over a second wavelength and a second portion of the second frame of data that will be transmitted over the first wavelength are determined (620).
  • the second frame of data is divided into 8-byte segments and the first portion includes multiple 8-byte segments of the second frame of data.
  • the first portion of the second frame of data and the second portion of the second frame of data are both transmitted to the second ONU without a sequence number. In such a situation, both the OLT and the second ONU agree on how various portions of the second frame of data are assigned to various different wavelengths.
  • an 8-byte XGEM header is added to both the first portion of the second frame of data and the second portion of the second frame of data.
  • a specified wavelength order is identified.
  • the specified wavelength order specifies an order in which portions of a single data frame are to be transmitted over available wavelengths.
  • the specified wavelength order is known to both the OLT and a given ONU.
  • the specified wavelength order is defined by wavelength numbers in ascending order (e.g., ⁇ first, then b, and A3).
  • the specified wavelength order can be defined by wavelength numbers in descending order or any other order that both the OLT and the given ONU agreed upon.
  • wavelength numbers are channel numbers assigned to wavelengths.
  • Transmitting the second portion of the second frame of data over the first wavelength includes the following operations. A determination is made that the first wavelength is next highest in the wavelength order after the second wavelength. The second portion of the second frame of data is transmitted over the first wavelength based on the determination that the first wavelength is the next highest in the wavelength order.
  • identifying the specified wavelength order includes identifying an NG-PON2 channel numbering corresponding to wavelengths being used to transmit data.
  • the specified wavelength order may be determined and controlled by a software process at the OLT, and communicated through a management channel to the bonding-capable ONUs prior to establishing bonded communications.
  • the second portion of the second frame of data is transmitted over the first wavelength based on the determination that the first wavelength is the first in the wavelength order.
  • a third frame of data is transmitted to the second ONU over the first and second wavelengths based on a specified wavelength order.
  • the first and second wavelengths carry no traffic right before transmitting the third frame of data (e.g., both wavelengths are available).
  • Various portions of the third frame of data are assigned round robin to the first and second wavelengths.
  • an 8-byte XGEM header is added with payload length for the third frame of data.
  • a 4-byte header is added with payload length for the third frame of data for each of the first and second wavelengths.
  • the OLT implements a dynamic allocation algorithm.
  • the dynamic allocation algorithm uses wavelength as a parameter in its bandwidth allocation for bonded entities (e.g., bonding-capable ONUs).
  • the dynamic allocation algorithm allocates time grants for different wavelengths of a bonded Transmission Container (TCONT) based on which wavelengths will be available and how much data is being transmitted when in a bonded mode of operation.
  • TCONT bonded Transmission Container
  • the OLT includes a bonding engine, which includes one or more processes that perform operations in the example process 600.
  • the one or more processes can be implemented in a dedicated hardware state machine, computer processor, and/or FPGA.
  • the OLT and the first and second ONUs are on a Next-Generation Passive Optical Network 2 (NG-PON2).
  • the OLT may separate its subsidiary components (e.g.
  • the example process 600 shown in FIG. 6 can be modified or reconfigured to include additional, fewer, or different actions (not shown in FIG. 6), which can be performed in the order shown or in a different order. For example, before 625, various portions of the second frame of data are assigned to various different wavelengths based on a specified ordering of the wavelengths by the OLT. In some implementations, one or more of the actions shown in FIG. 6 can be repeated or iterated, for example, until a terminating condition is reached. In some
  • one or more of the individual actions shown in FIG. 6 can be executed as multiple separate actions, or one or more subsets of the actions shown in FIG. 6 can be combined and executed as a single action. In some implementations, one or more of the individual actions shown in FIG. 6 may also be omitted from the example process 600.
  • FIG. 7 is a flow chart of an example scheduling process 700 for PON wavelength bonding of the OLT downstream (point-to-multipoint) transmission.
  • the example scheduling process 700 can be performed, for example, by one or more telecommunications devices, such as those described with reference to FIG. 1A (e.g., OLT 106).
  • the example scheduling process 700 can also be implemented as instructions stored on a non-transitory, computer-readable medium that, when executed by one or more telecommunications devices, configures the one or more
  • a frame of data is received (705).
  • the frame of data is received by an OLT to be transmitted to an ONU.
  • One or more wavelengths that are eligible to carry the frame of data are determined (710).
  • a time when each of the one or more eligible wavelengths will be ready to start carrying the frame of data is determined (715).
  • the determination e.g., 710, 715) is made by checking the transmission schedule on each of the one or more wavelengths.
  • a finishing time of the transmission of the frame of data is determined before the transmission of the frame of data (720).
  • the finishing time can be determined based on a preferred distribution of the frame of data across the one or more wavelengths. The preferred distribution distributes the frame of data across the one or more wavelengths so that transmissions of various portions of the frame of data on the one or more wavelengths end at the same time or substantially
  • XGEM headers for each of the one or more wavelengths are determined (725).
  • the XGEM headers and pay load (e.g., various portions of the frame of data) for each of the one or more wavelengths are queued up for transmission (730).
  • the example scheduling process 700 shown in FIG. 7 can be modified or reconfigured to include additional, fewer, or different actions (not shown in FIG. 7), which can be performed in the order shown or in a different order. For example, before 730, other frames of data destined only for "busy" wavelengths are prevented from requesting the next allocation. In some implementations, one or more of the actions shown in FIG. 7 can be repeated or iterated, for example, until a terminating condition is reached. For example, after 730 the example scheduling process 700 may return to 705 to receive another frame of data. In some implementations, one or more of the individual actions shown in FIG. 7 can be executed as multiple separate actions, or one or more subsets of the actions shown in FIG. 7 can be combined and executed as a single action. In some implementations, one or more of the individual actions shown in FIG. 7 may also be omitted from the example scheduling process 700.

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Abstract

La présente invention concerne des procédés, des systèmes et un appareil pour la liaison de longueur d'onde de réseau optique passif (PON). Dans un aspect, une première trame de données pour une première unité de réseau optique (ONU) est transmise par un terminal de ligne optique (OLT) sur une première longueur d'onde. Tandis que la première trame de données est transmise à la première ONU sur la première longueur d'onde, une première partie d'une deuxième trame de données pour une deuxième ONU est transmise par l'OLT sur une deuxième longueur d'onde. Une fois que la transmission de la première trame de données sur la première longueur d'onde est terminée et tandis que la première partie de la deuxième trame de données est encore transmise à la deuxième ONU sur la deuxième longueur d'onde, une deuxième partie de la deuxième trame de données pour la deuxième ONU est transmise par l'OLT sur la première longueur d'onde.
EP16810576.5A 2015-12-01 2016-11-28 Liaison de longueur d'onde de pon pour services à haut débit Active EP3384681B1 (fr)

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US15/341,677 US9924248B2 (en) 2015-12-01 2016-11-02 Pon wavelength bonding for high-rate services
PCT/US2016/063870 WO2017095749A1 (fr) 2015-12-01 2016-11-28 Liaison de longueur d'onde de pon pour services à haut débit

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EP2888889B1 (fr) * 2012-08-24 2020-03-25 Avago Technologies International Sales Pte. Limited Liaison de canal pour un réseau optique passif ethernet sur câble coaxial (epoc)
US10177871B2 (en) * 2015-07-10 2019-01-08 Futurewei Technologies, Inc. High data rate extension with bonding
CN106788855B (zh) * 2015-11-23 2018-12-07 华为技术有限公司 一种灵活以太网业务的光传送网承载方法及装置
CN107317647B (zh) * 2016-04-26 2019-07-26 中兴通讯股份有限公司 通道的调整方法、装置及系统
CN110073672B (zh) * 2016-12-30 2021-10-15 华为技术有限公司 一种管理光网络单元onu的方法、装置及系统
WO2021078093A1 (fr) * 2019-10-25 2021-04-29 中兴通讯股份有限公司 Procédé et appareil d'envoi de données, procédé et appareil de réception de données, nœud de communication et support de stockage
CN111601186A (zh) 2019-12-31 2020-08-28 中兴通讯股份有限公司 Pon多通道动态绑定传输方法、pon节点和存储介

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US8837508B2 (en) * 2008-07-30 2014-09-16 Adtran, Inc. Systems and methods for allocating bonding engines in network communications
EP2838217A1 (fr) * 2013-08-13 2015-02-18 Alcatel Lucent Communication optique avec paquet optique à longueurs d'onde multiples
US10177871B2 (en) * 2015-07-10 2019-01-08 Futurewei Technologies, Inc. High data rate extension with bonding
US10009110B2 (en) * 2015-09-09 2018-06-26 Futurewei Technologies, Inc. Channel bonding in passive optical networks

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